// This file is part of the AliceVision project.
// Copyright (c) 2017 AliceVision contributors.
// Copyright (c) 2012 openMVG contributors.
// This Source Code Form is subject to the terms of the Mozilla Public License,
// v. 2.0. If a copy of the MPL was not distributed with this file,
// You can obtain one at https://mozilla.org/MPL/2.0/.

#include <aliceVision/sfmData/SfMData.hpp>
#include <aliceVision/sfmDataIO/sfmDataIO.hpp>
#include <aliceVision/sfm/pipeline/regionsIO.hpp>
#include <aliceVision/feature/imageDescriberCommon.hpp>
#include <aliceVision/sfm/pipeline/panorama/ReconstructionEngine_panorama.hpp>
#include <aliceVision/sfm/utils/alignment.hpp>
#include <aliceVision/system/Timer.hpp>
#include <aliceVision/system/Logger.hpp>
#include <aliceVision/system/main.hpp>
#include <aliceVision/utils/filesIO.hpp>
#include <aliceVision/cmdline/cmdline.hpp>
#include <aliceVision/image/all.hpp>

#include <boost/program_options.hpp>

#include <OpenImageIO/imageio.h>
#include <OpenImageIO/imagebuf.h>
#include <OpenImageIO/imagebufalgo.h>

#include <cstdlib>
#include <filesystem>

// These constants define the current software version.
// They must be updated when the command line is changed.
#define ALICEVISION_SOFTWARE_VERSION_MAJOR 1
#define ALICEVISION_SOFTWARE_VERSION_MINOR 0

using namespace aliceVision;

namespace po = boost::program_options;
namespace fs = std::filesystem;

int aliceVision_main(int argc, char** argv)
{
    // command-line parameters
    std::string sfmDataFilename;
    std::vector<std::string> featuresFolders;
    std::vector<std::string> matchesFolders;
    std::string outputSfMDataFilepath;
    std::string outputViewsAndPosesFilepath;

    // user optional parameters
    std::string describerTypesName = feature::EImageDescriberType_enumToString(feature::EImageDescriberType::SIFT);
    bool filterMatches = false;
    bool refine = true;
    float offsetLongitude = 0.0f;
    float offsetLatitude = 0.0f;
    bool useAutomaticReferenceFrame = true;

    int randomSeed = std::mt19937::default_seed;

    sfm::ReconstructionEngine_panorama::Params params;

    // clang-format off
    po::options_description requiredParams("Required parameters");
    requiredParams.add_options()
        ("input,i", po::value<std::string>(&sfmDataFilename)->required(),
         "SfMData file.")
        ("output,o", po::value<std::string>(&outputSfMDataFilepath)->required(),
         "Path of the output SfMData file.")
        ("featuresFolders,f", po::value<std::vector<std::string>>(&featuresFolders)->multitoken()->required(),
         "Path to folder(s) containing the extracted features.")
        ("matchesFolders,m", po::value<std::vector<std::string>>(&matchesFolders)->multitoken()->required(),
         "Path to folder(s) in which computed matches are stored.");

    po::options_description optionalParams("Optional parameters");
    optionalParams.add_options()
        ("describerTypes,d", po::value<std::string>(&describerTypesName)->default_value(describerTypesName),
         feature::EImageDescriberType_informations().c_str())
        ("rotationAveraging", po::value<sfm::ERotationAveragingMethod>(&params.eRotationAveragingMethod)->default_value(params.eRotationAveragingMethod),
         "* 1: L1 minimization\n"
         "* 2: L2 minimization")
        ("relativeRotation", po::value<sfm::ERelativeRotationMethod>(&params.eRelativeRotationMethod)->default_value(params.eRelativeRotationMethod),
         "* from essential matrix\n"
         "* from rotation matrix\n"
         "* from homography matrix")
        ("rotationAveragingWeighting", po::value<bool>(&params.rotationAveragingWeighting)->default_value(params.rotationAveragingWeighting),
         "Use weighting of image links during rotation averaging.")
        ("offsetLongitude", po::value<float>(&offsetLongitude)->default_value(offsetLongitude),
         "Offset to camera longitude.")
        ("offsetLatitude", po::value<float>(&offsetLatitude)->default_value(offsetLatitude),
         "Offset to camera latitude.")
        ("filterMatches", po::value<bool>(&filterMatches)->default_value(filterMatches),
         "Filter matches before solving the Panorama.")
        ("refine", po::value<bool>(&refine)->default_value(refine),
         "Refine cameras with a Bundle Adjustment")
        ("lockAllIntrinsics", po::value<bool>(&params.lockAllIntrinsics)->default_value(params.lockAllIntrinsics),
         "Force lock of all camera intrinsic parameters, so they will not be refined during Bundle Adjustment.")
        ("maxAngleToPrior", po::value<double>(&params.maxAngleToPrior)->default_value(params.maxAngleToPrior),
         "Maximal angle allowed regarding the input prior.")
        ("maxAngleToPriorRefined", po::value<double>(&params.maxAngleToPriorRefined)->default_value(params.maxAngleToPriorRefined),
         "Maximal angle allowed regarding the input prior after refinement.")
        ("maxAngularError", po::value<double>(&params.maxAngularError)->default_value(params.maxAngularError),
         "Maximal angular error in global rotation averaging.")
        ("intermediateRefineWithFocal", po::value<bool>(&params.intermediateRefineWithFocal)->default_value(params.intermediateRefineWithFocal),
         "Add an intermediate refine with rotation+focal in the different BA steps.")
        ("intermediateRefineWithFocalDist", po::value<bool>(&params.intermediateRefineWithFocalDist)->default_value(params.intermediateRefineWithFocalDist),
         "Add an intermediate refine with rotation+focal+distortion in the different BA steps.")
        ("outputViewsAndPoses", po::value<std::string>(&outputViewsAndPosesFilepath),
         "Path of the output SfMData file.")
        ("randomSeed", po::value<int>(&randomSeed)->default_value(randomSeed),
         "This seed value will generate a sequence using a linear random generator. Set -1 to use a random seed.");
    // clang-format on

    CmdLine cmdline("Estimates the orientation of a camera around a nodal point for the creation of a 360° panorama.\n"
                    "AliceVision panoramaEstimation");
    cmdline.add(requiredParams);
    cmdline.add(optionalParams);
    if (!cmdline.execute(argc, argv))
    {
        return EXIT_FAILURE;
    }

    if (params.eRotationAveragingMethod < sfm::ROTATION_AVERAGING_L1 || params.eRotationAveragingMethod > sfm::ROTATION_AVERAGING_L2)
    {
        ALICEVISION_LOG_ERROR("Rotation averaging method is invalid");
        return EXIT_FAILURE;
    }

    if (params.eRelativeRotationMethod < sfm::RELATIVE_ROTATION_FROM_E || params.eRelativeRotationMethod > sfm::RELATIVE_ROTATION_FROM_H)
    {
        ALICEVISION_LOG_ERROR("Relative rotation method is invalid");
        return EXIT_FAILURE;
    }

    // load input SfMData scene
    sfmData::SfMData inputSfmData;
    if (!sfmDataIO::load(inputSfmData, sfmDataFilename, sfmDataIO::ESfMData(sfmDataIO::VIEWS | sfmDataIO::INTRINSICS | sfmDataIO::EXTRINSICS)))
    {
        ALICEVISION_LOG_ERROR("The input SfMData file '" << sfmDataFilename << "' cannot be read.");
        return EXIT_FAILURE;
    }

    if (!inputSfmData.getLandmarks().empty())
    {
        ALICEVISION_LOG_ERROR("Partially computed SfMData is not currently supported in PanoramaEstimation.");
        return EXIT_FAILURE;
    }

    if (!inputSfmData.getRigs().empty())
    {
        ALICEVISION_LOG_ERROR("Rigs are not currently supported in PanoramaEstimation.");
        return EXIT_FAILURE;
    }

    /* Store the pose c1_R_o of the prior */
    sfmData::Poses& initial_poses = inputSfmData.getPoses();
    Eigen::Matrix3d c1_R_oprior = Eigen::Matrix3d::Identity();
    if (!initial_poses.empty())
    {
        c1_R_oprior = initial_poses.begin()->second.getTransform().rotation();
    }

    // get describerTypes
    const std::vector<feature::EImageDescriberType> describerTypes = feature::EImageDescriberType_stringToEnums(describerTypesName);

    // features reading
    feature::FeaturesPerView featuresPerView;
    if (!sfm::loadFeaturesPerView(featuresPerView, inputSfmData, featuresFolders, describerTypes))
    {
        ALICEVISION_LOG_ERROR("Invalid features");
        return EXIT_FAILURE;
    }

    // matches reading
    // Load the match file (try to read the two matches file formats).
    matching::PairwiseMatches pairwiseMatches;
    if (!sfm::loadPairwiseMatches(pairwiseMatches, inputSfmData, matchesFolders, describerTypes))
    {
        ALICEVISION_LOG_ERROR("Unable to load matches files from: " << matchesFolders);
        return EXIT_FAILURE;
    }

    const std::string outDirectory = fs::path(outputSfMDataFilepath).parent_path().string();

    if (!utils::exists(outDirectory))
    {
        ALICEVISION_LOG_ERROR("Output folder does not exist: " << outDirectory);
        return EXIT_FAILURE;
    }

    // Panorama reconstruction process
    aliceVision::system::Timer timer;
    sfm::ReconstructionEngine_panorama sfmEngine(inputSfmData, params, outDirectory, (fs::path(outDirectory) / "sfm_log.html").string());

    sfmEngine.initRandomSeed(randomSeed);

    // configure the featuresPerView & the matches_provider
    sfmEngine.setFeaturesProvider(&featuresPerView);
    sfmEngine.setMatchesProvider(&pairwiseMatches);

    if (filterMatches)
    {
        sfmEngine.filterMatches();
    }

    if (!sfmEngine.process())
    {
        return EXIT_FAILURE;
    }

    // set featuresFolders and matchesFolders relative paths
    {
        sfmEngine.getSfMData().addFeaturesFolders(featuresFolders);
        sfmEngine.getSfMData().addMatchesFolders(matchesFolders);
        sfmEngine.getSfMData().setAbsolutePath(outputSfMDataFilepath);
    }

    if (refine)
    {
        sfmDataIO::save(sfmEngine.getSfMData(), (fs::path(outDirectory) / "BA_before.abc").string(), sfmDataIO::ESfMData::ALL);
        if (!sfmEngine.adjust())
        {
            return EXIT_FAILURE;
        }
        sfmDataIO::save(sfmEngine.getSfMData(), (fs::path(outDirectory) / "BA_after.abc").string(), sfmDataIO::ESfMData::ALL);
    }

    sfmData::SfMData& outSfmData = sfmEngine.getSfMData();

    // If an initial set of poses was available, make sure at least one pose is aligned with it
    // Otherwise take the middle view (sorted over time)
    sfmData::Poses& final_poses = outSfmData.getPoses();

    if (!final_poses.empty())
    {
        Eigen::Matrix3d ocur_R_oprior = Eigen::Matrix3d::Identity();

        if (initial_poses.empty())
        {
            if (useAutomaticReferenceFrame)
            {
                double S = 1.0;
                Eigen::Matrix3d R;
                Vec3 t;
                sfm::computeNewCoordinateSystemFromCamerasXAxis(outSfmData, S, R, t);
                ocur_R_oprior = R.transpose();
            }
            else
            {
                std::vector<std::pair<int64_t, IndexT>> sorted_views;

                // Sort views per timestamps
                for (auto v : outSfmData.getViews())
                {
                    int64_t t = v.second->getImage().getMetadataDateTimestamp();
                    sorted_views.push_back(std::make_pair(t, v.second->getPoseId()));
                }
                std::sort(sorted_views.begin(), sorted_views.end());

                // Get the view which was taken at the middle of the sequence
                int median = sorted_views.size() / 2;
                IndexT poseId = sorted_views[median].second;

                // Set as reference
                ocur_R_oprior = final_poses[poseId].getTransform().rotation().transpose();
            }
        }
        else
        {
            Eigen::Matrix3d c1_R_ocur = final_poses.begin()->second.getTransform().rotation();
            ocur_R_oprior = c1_R_ocur.transpose() * c1_R_oprior;
        }

        for (auto& pose : final_poses)
        {
            geometry::Pose3 p = pose.second.getTransform();

            Eigen::Matrix3d c_R_oprior = p.rotation() * ocur_R_oprior;

            p.setRotation(c_R_oprior);
            pose.second.setTransform(p);
        }
    }

    // Final report
    ALICEVISION_LOG_INFO("Panorama solve took (s): " << timer.elapsed());
    ALICEVISION_LOG_INFO("Generating HTML report...");
    sfm::generateSfMReport(outSfmData, (fs::path(outDirectory) / "sfm_report.html").string());

    // Add offsets to rotations
    for (auto& pose : outSfmData.getPoses())
    {
        geometry::Pose3 p = pose.second.getTransform();
        Eigen::Matrix3d matLongitude = Eigen::AngleAxisd(degreeToRadian(offsetLongitude), Vec3(0, 1, 0)).toRotationMatrix();
        Eigen::Matrix3d matLatitude = Eigen::AngleAxisd(degreeToRadian(offsetLatitude), Vec3(1, 0, 0)).toRotationMatrix();
        Eigen::Matrix3d newR = p.rotation() * matLongitude * matLatitude;
        p.setRotation(newR);
        pose.second.setTransform(p);
    }

    sfmEngine.buildLandmarks();
    sfmEngine.colorize();

    {
        std::set<IndexT> viewsWithObservations;
        for (const auto& landmarkIt : outSfmData.getLandmarks())
        {
            for (const auto& obsIt : landmarkIt.second.getObservations())
            {
                viewsWithObservations.insert(obsIt.first);
            }
        }

        ALICEVISION_LOG_INFO("Panorama results:" << std::endl
                                                 << "\t- # input images: " << outSfmData.getViews().size() << std::endl
                                                 << "\t- # cameras calibrated: " << outSfmData.getValidViews().size() << std::endl
                                                 << "\t- # cameras with observations: " << viewsWithObservations.size() << std::endl
                                                 << "\t- # landmarks: " << outSfmData.getLandmarks().size());
    }

    // Export to disk computed scene (data & visualizable results)
    ALICEVISION_LOG_INFO("Export SfMData to disk");
    sfmDataIO::save(outSfmData, outputSfMDataFilepath, sfmDataIO::ESfMData::ALL);
    sfmDataIO::save(outSfmData, (fs::path(outDirectory) / "cloud_and_poses.ply").string(), sfmDataIO::ESfMData::ALL);

    if (!outputViewsAndPosesFilepath.empty())
    {
        sfmDataIO::save(
          outSfmData, outputViewsAndPosesFilepath, sfmDataIO::ESfMData(sfmDataIO::VIEWS | sfmDataIO::EXTRINSICS | sfmDataIO::INTRINSICS));
    }

    return EXIT_SUCCESS;
}
